src/pkg/runtime/softfloat_arm.c - go - Git at Google

 // Copyright 2009 The Go Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 // Software floating point interpretaton of ARM 7500 FP instructions.
 // The interpretation is not bit compatible with the 7500.
 // It uses true little-endian doubles, while the 7500 used mixed-endian.

 #include "runtime.h"

 #define CPSR 14
 #define FLAGS_N (1 << 31)
 #define FLAGS_Z (1 << 30)
 #define FLAGS_C (1 << 29)
 #define FLAGS_V (1 << 28)

 void	runtime·abort(void);
 void	math·sqrtC(uint64, uint64*);

 static	uint32	trace = 0;

 static void
 fabort(void)
 {
 	if (1) {
 		runtime·printf("Unsupported floating point instruction\n");
 		runtime·abort();
 	}
 }

 static void
 putf(uint32 reg, uint32 val)
 {
 	m->freglo[reg] = val;
 }

 static void
 putd(uint32 reg, uint64 val)
 {
 	m->freglo[reg] = (uint32)val;
 	m->freghi[reg] = (uint32)(val>>32);
 }

 static uint64
 getd(uint32 reg)
 {
 	return (uint64)m->freglo[reg] | ((uint64)m->freghi[reg]<<32);
 }

 static void
 fprint(void)
 {
 	uint32 i;
 	for (i = 0; i < 16; i++) {
 		runtime·printf("\tf%d:\t%X %X\n", i, m->freghi[i], m->freglo[i]);
 	}
 }

 static uint32
 d2f(uint64 d)
 {
 	uint32 x;

 	runtime·f64to32c(d, &x);
 	return x;
 }

 static uint64
 f2d(uint32 f)
 {
 	uint64 x;

 	runtime·f32to64c(f, &x);
 	return x;
 }

 static uint32
 fstatus(bool nan, int32 cmp)
 {
 	if(nan)
 		return FLAGS_C | FLAGS_V;
 	if(cmp == 0)
 		return FLAGS_Z | FLAGS_C;
 	if(cmp < 0)
 		return FLAGS_N;
 	return FLAGS_C;
 }

 // returns number of words that the fp instruction
 // is occupying, 0 if next instruction isn't float.
 static uint32
 stepflt(uint32 *pc, uint32 *regs)
 {
 	uint32 i, regd, regm, regn;
 	int32 delta;
 	uint32 *addr;
 	uint64 uval;
 	int64 sval;
 	bool nan, ok;
 	int32 cmp;

 	i = *pc;

 	if(trace)
 		runtime·printf("stepflt %p %x\n", pc, i);

 	// special cases
 	if((i&0xfffff000) == 0xe59fb000) {
 		// load r11 from pc-relative address.
 		// might be part of a floating point move
 		// (or might not, but no harm in simulating
 		// one instruction too many).
 		addr = (uint32*)((uint8*)pc + (i&0xfff) + 8);
 		regs[11] = addr[0];

 		if(trace)
 			runtime·printf("*** cpu R[%d] = *(%p) %x\n",
 				11, addr, regs[11]);
 		return 1;
 	}
 	if(i == 0xe08bb00d) {
 		// add sp to r11.
 		// might be part of a large stack offset address
 		// (or might not, but again no harm done).
 		regs[11] += regs[13];

 		if(trace)
 			runtime·printf("*** cpu R[%d] += R[%d] %x\n",
 				11, 13, regs[11]);
 		return 1;
 	}
 	if(i == 0xeef1fa10) {
 		regs[CPSR] = (regs[CPSR]&0x0fffffff) | m->fflag;

 		if(trace)
 			runtime·printf("*** fpsr R[CPSR] = F[CPSR] %x\n", regs[CPSR]);
 		return 1;
 	}
 	if((i&0xff000000) == 0xea000000) {
 		// unconditional branch
 		// can happen in the middle of floating point
 		// if the linker decides it is time to lay down
 		// a sequence of instruction stream constants.
 		delta = i&0xffffff;
 		delta = (delta<<8) >> 8;	// sign extend

 		if(trace)
 			runtime·printf("*** cpu PC += %x\n", (delta+2)*4);
 		return delta+2;
 	}

 	goto stage1;

 stage1:	// load/store regn is cpureg, regm is 8bit offset
 	regd = i>>12 & 0xf;
 	regn = i>>16 & 0xf;
 	regm = (i & 0xff) << 2;	// PLUS or MINUS ??

 	switch(i & 0xfff00f00) {
 	default:
 		goto stage2;

 	case 0xed900a00:	// single load
 		addr = (uint32*)(regs[regn] + regm);
 		m->freglo[regd] = addr[0];

 		if(trace)
 			runtime·printf("*** load F[%d] = %x\n",
 				regd, m->freglo[regd]);
 		break;

 	case 0xed900b00:	// double load
 		addr = (uint32*)(regs[regn] + regm);
 		m->freglo[regd] = addr[0];
 		m->freghi[regd] = addr[1];

 		if(trace)
 			runtime·printf("*** load D[%d] = %x-%x\n",
 				regd, m->freghi[regd], m->freglo[regd]);
 		break;

 	case 0xed800a00:	// single store
 		addr = (uint32*)(regs[regn] + regm);
 		addr[0] = m->freglo[regd];

 		if(trace)
 			runtime·printf("*** *(%p) = %x\n",
 				addr, addr[0]);
 		break;

 	case 0xed800b00:	// double store
 		addr = (uint32*)(regs[regn] + regm);
 		addr[0] = m->freglo[regd];
 		addr[1] = m->freghi[regd];

 		if(trace)
 			runtime·printf("*** *(%p) = %x-%x\n",
 				addr, addr[1], addr[0]);
 		break;
 	}
 	return 1;

 stage2:	// regd, regm, regn are 4bit variables
 	regm = i>>0 & 0xf;
 	switch(i & 0xfff00ff0) {
 	default:
 		goto stage3;

 	case 0xf3000110:	// veor
 		m->freglo[regd] = m->freglo[regm]^m->freglo[regn];
 		m->freghi[regd] = m->freghi[regm]^m->freghi[regn];

 		if(trace)
 			runtime·printf("*** veor D[%d] = %x-%x\n",
 				regd, m->freghi[regd], m->freglo[regd]);
 		break;

 	case 0xeeb00b00:	// D[regd] = const(regn,regm)
 		regn = (regn<<4) | regm;
 		regm = 0x40000000UL;
 		if(regn & 0x80)
 			regm |= 0x80000000UL;
 		if(regn & 0x40)
 			regm ^= 0x7fc00000UL;
 		regm |= (regn & 0x3f) << 16;
 		m->freglo[regd] = 0;
 		m->freghi[regd] = regm;

 		if(trace)
 			runtime·printf("*** immed D[%d] = %x-%x\n",
 				regd, m->freghi[regd], m->freglo[regd]);
 		break;

 	case 0xeeb00a00:	// F[regd] = const(regn,regm)
 		regn = (regn<<4) | regm;
 		regm = 0x40000000UL;
 		if(regn & 0x80)
 			regm |= 0x80000000UL;
 		if(regn & 0x40)
 			regm ^= 0x7e000000UL;
 		regm |= (regn & 0x3f) << 19;
 		m->freglo[regd] = regm;

 		if(trace)
 			runtime·printf("*** immed D[%d] = %x\n",
 				regd, m->freglo[regd]);
 		break;

 	case 0xee300b00:	// D[regd] = D[regn]+D[regm]
 		runtime·fadd64c(getd(regn), getd(regm), &uval);
 		putd(regd, uval);

 		if(trace)
 			runtime·printf("*** add D[%d] = D[%d]+D[%d] %x-%x\n",
 				regd, regn, regm, m->freghi[regd], m->freglo[regd]);
 		break;

 	case 0xee300a00:	// F[regd] = F[regn]+F[regm]
 		runtime·fadd64c(f2d(m->freglo[regn]), f2d(m->freglo[regm]), &uval);
 		m->freglo[regd] = d2f(uval);

 		if(trace)
 			runtime·printf("*** add F[%d] = F[%d]+F[%d] %x\n",
 				regd, regn, regm, m->freglo[regd]);
 		break;

 	case 0xee300b40:	// D[regd] = D[regn]-D[regm]
 		runtime·fsub64c(getd(regn), getd(regm), &uval);
 		putd(regd, uval);

 		if(trace)
 			runtime·printf("*** sub D[%d] = D[%d]-D[%d] %x-%x\n",
 				regd, regn, regm, m->freghi[regd], m->freglo[regd]);
 		break;

 	case 0xee300a40:	// F[regd] = F[regn]-F[regm]
 		runtime·fsub64c(f2d(m->freglo[regn]), f2d(m->freglo[regm]), &uval);
 		m->freglo[regd] = d2f(uval);

 		if(trace)
 			runtime·printf("*** sub F[%d] = F[%d]-F[%d] %x\n",
 				regd, regn, regm, m->freglo[regd]);
 		break;

 	case 0xee200b00:	// D[regd] = D[regn]*D[regm]
 		runtime·fmul64c(getd(regn), getd(regm), &uval);
 		putd(regd, uval);

 		if(trace)
 			runtime·printf("*** mul D[%d] = D[%d]*D[%d] %x-%x\n",
 				regd, regn, regm, m->freghi[regd], m->freglo[regd]);
 		break;

 	case 0xee200a00:	// F[regd] = F[regn]*F[regm]
 		runtime·fmul64c(f2d(m->freglo[regn]), f2d(m->freglo[regm]), &uval);
 		m->freglo[regd] = d2f(uval);

 		if(trace)
 			runtime·printf("*** mul F[%d] = F[%d]*F[%d] %x\n",
 				regd, regn, regm, m->freglo[regd]);
 		break;

 	case 0xee800b00:	// D[regd] = D[regn]/D[regm]
 		runtime·fdiv64c(getd(regn), getd(regm), &uval);
 		putd(regd, uval);

 		if(trace)
 			runtime·printf("*** div D[%d] = D[%d]/D[%d] %x-%x\n",
 				regd, regn, regm, m->freghi[regd], m->freglo[regd]);
 		break;

 	case 0xee800a00:	// F[regd] = F[regn]/F[regm]
 		runtime·fdiv64c(f2d(m->freglo[regn]), f2d(m->freglo[regm]), &uval);
 		m->freglo[regd] = d2f(uval);

 		if(trace)
 			runtime·printf("*** div F[%d] = F[%d]/F[%d] %x\n",
 				regd, regn, regm, m->freglo[regd]);
 		break;

 	case 0xee000b10:	// S[regn] = R[regd] (MOVW) (regm ignored)
 		m->freglo[regn] = regs[regd];

 		if(trace)
 			runtime·printf("*** cpy S[%d] = R[%d] %x\n",
 				regn, regd, m->freglo[regn]);
 		break;

 	case 0xee100b10:	// R[regd] = S[regn] (MOVW) (regm ignored)
 		regs[regd] = m->freglo[regn];

 		if(trace)
 			runtime·printf("*** cpy R[%d] = S[%d] %x\n",
 				regd, regn, regs[regd]);
 		break;
 	}
 	return 1;

 stage3:	// regd, regm are 4bit variables
 	switch(i & 0xffff0ff0) {
 	default:
 		goto done;

 	case 0xeeb00a40:	// F[regd] = F[regm] (MOVF)
 		m->freglo[regd] = m->freglo[regm];

 		if(trace)
 			runtime·printf("*** F[%d] = F[%d] %x\n",
 				regd, regm, m->freglo[regd]);
 		break;

 	case 0xeeb00b40:	// D[regd] = D[regm] (MOVD)
 		m->freglo[regd] = m->freglo[regm];
 		m->freghi[regd] = m->freghi[regm];

 		if(trace)
 			runtime·printf("*** D[%d] = D[%d] %x-%x\n",
 				regd, regm, m->freghi[regd], m->freglo[regd]);
 		break;

 	case 0xeeb10bc0:	// D[regd] = sqrt D[regm]
 		math·sqrtC(getd(regm), &uval);
 		putd(regd, uval);

 		if(trace)
 			runtime·printf("*** D[%d] = sqrt D[%d] %x-%x\n",
 				regd, regm, m->freghi[regd], m->freglo[regd]);
 		break;

 	case 0xeeb40bc0:	// D[regd] :: D[regm] (CMPD)
 		runtime·fcmp64c(getd(regd), getd(regm), &cmp, &nan);
 		m->fflag = fstatus(nan, cmp);

 		if(trace)
 			runtime·printf("*** cmp D[%d]::D[%d] %x\n",
 				regd, regm, m->fflag);
 		break;

 	case 0xeeb40ac0:	// F[regd] :: F[regm] (CMPF)
 		runtime·fcmp64c(f2d(m->freglo[regd]), f2d(m->freglo[regm]), &cmp, &nan);
 		m->fflag = fstatus(nan, cmp);

 		if(trace)
 			runtime·printf("*** cmp F[%d]::F[%d] %x\n",
 				regd, regm, m->fflag);
 		break;

 	case 0xeeb70ac0:	// D[regd] = F[regm] (MOVFD)
 		putd(regd, f2d(m->freglo[regm]));

 		if(trace)
 			runtime·printf("*** f2d D[%d]=F[%d] %x-%x\n",
 				regd, regm, m->freghi[regd], m->freglo[regd]);
 		break;

 	case 0xeeb70bc0:	// F[regd] = D[regm] (MOVDF)
 		m->freglo[regd] = d2f(getd(regm));

 		if(trace)
 			runtime·printf("*** d2f F[%d]=D[%d] %x-%x\n",
 				regd, regm, m->freghi[regd], m->freglo[regd]);
 		break;

 	case 0xeebd0ac0:	// S[regd] = F[regm] (MOVFW)
 		runtime·f64tointc(f2d(m->freglo[regm]), &sval, &ok);
 		if(!ok || (int32)sval != sval)
 			sval = 0;
 		m->freglo[regd] = sval;

 		if(trace)
 			runtime·printf("*** fix S[%d]=F[%d] %x\n",
 				regd, regm, m->freglo[regd]);
 		break;

 	case 0xeebc0ac0:	// S[regd] = F[regm] (MOVFW.U)
 		runtime·f64tointc(f2d(m->freglo[regm]), &sval, &ok);
 		if(!ok || (uint32)sval != sval)
 			sval = 0;
 		m->freglo[regd] = sval;

 		if(trace)
 			runtime·printf("*** fix unsigned S[%d]=F[%d] %x\n",
 				regd, regm, m->freglo[regd]);
 		break;

 	case 0xeebd0bc0:	// S[regd] = D[regm] (MOVDW)
 		runtime·f64tointc(getd(regm), &sval, &ok);
 		if(!ok || (int32)sval != sval)
 			sval = 0;
 		m->freglo[regd] = sval;

 		if(trace)
 			runtime·printf("*** fix S[%d]=D[%d] %x\n",
 				regd, regm, m->freglo[regd]);
 		break;

 	case 0xeebc0bc0:	// S[regd] = D[regm] (MOVDW.U)
 		runtime·f64tointc(getd(regm), &sval, &ok);
 		if(!ok || (uint32)sval != sval)
 			sval = 0;
 		m->freglo[regd] = sval;

 		if(trace)
 			runtime·printf("*** fix unsigned S[%d]=D[%d] %x\n",
 				regd, regm, m->freglo[regd]);
 		break;

 	case 0xeeb80ac0:	// D[regd] = S[regm] (MOVWF)
 		cmp = m->freglo[regm];
 		if(cmp < 0) {
 			runtime·fintto64c(-cmp, &uval);
 			putf(regd, d2f(uval));
 			m->freglo[regd] ^= 0x80000000;
 		} else {
 			runtime·fintto64c(cmp, &uval);
 			putf(regd, d2f(uval));
 		}

 		if(trace)
 			runtime·printf("*** float D[%d]=S[%d] %x-%x\n",
 				regd, regm, m->freghi[regd], m->freglo[regd]);
 		break;

 	case 0xeeb80a40:	// D[regd] = S[regm] (MOVWF.U)
 		runtime·fintto64c(m->freglo[regm], &uval);
 		putf(regd, d2f(uval));

 		if(trace)
 			runtime·printf("*** float unsigned D[%d]=S[%d] %x-%x\n",
 				regd, regm, m->freghi[regd], m->freglo[regd]);
 		break;

 	case 0xeeb80bc0:	// D[regd] = S[regm] (MOVWD)
 		cmp = m->freglo[regm];
 		if(cmp < 0) {
 			runtime·fintto64c(-cmp, &uval);
 			putd(regd, uval);
 			m->freghi[regd] ^= 0x80000000;
 		} else {
 			runtime·fintto64c(cmp, &uval);
 			putd(regd, uval);
 		}

 		if(trace)
 			runtime·printf("*** float D[%d]=S[%d] %x-%x\n",
 				regd, regm, m->freghi[regd], m->freglo[regd]);
 		break;

 	case 0xeeb80b40:	// D[regd] = S[regm] (MOVWD.U)
 		runtime·fintto64c(m->freglo[regm], &uval);
 		putd(regd, uval);

 		if(trace)
 			runtime·printf("*** float unsigned D[%d]=S[%d] %x-%x\n",
 				regd, regm, m->freghi[regd], m->freglo[regd]);
 		break;
 	}
 	return 1;

 done:
 	if((i&0xff000000) == 0xee000000 ||
 	   (i&0xff000000) == 0xed000000) {
 		runtime·printf("stepflt %p %x\n", pc, i);
 		fabort();
 	}
 	return 0;
 }

 #pragma textflag 7
 uint32*
 runtime·_sfloat2(uint32 *lr, uint32 r0)
 {
 	uint32 skip;

 	skip = stepflt(lr, &r0);
 	if(skip == 0) {
 		runtime·printf("sfloat2 %p %x\n", lr, *lr);
 		fabort(); // not ok to fail first instruction
 	}

 	lr += skip;
 	while(skip = stepflt(lr, &r0))
 		lr += skip;
 	return lr;
 }
	// Copyright 2009 The Go Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	// Software floating point interpretaton of ARM 7500 FP instructions.
	// The interpretation is not bit compatible with the 7500.
	// It uses true little-endian doubles, while the 7500 used mixed-endian.

	#include "runtime.h"

	#define CPSR 14
	#define FLAGS_N (1 << 31)
	#define FLAGS_Z (1 << 30)
	#define FLAGS_C (1 << 29)
	#define FLAGS_V (1 << 28)

	void runtime·abort(void);
	void math·sqrtC(uint64, uint64*);

	static uint32 trace = 0;

	static void
	fabort(void)
	{
	if (1) {
	runtime·printf("Unsupported floating point instruction\n");
	runtime·abort();
	}
	}

	static void
	putf(uint32 reg, uint32 val)
	{
	m->freglo[reg] = val;
	}

	static void
	putd(uint32 reg, uint64 val)
	{
	m->freglo[reg] = (uint32)val;
	m->freghi[reg] = (uint32)(val>>32);
	}

	static uint64
	getd(uint32 reg)
	{
	return (uint64)m->freglo[reg] \| ((uint64)m->freghi[reg]<<32);
	}

	static void
	fprint(void)
	{
	uint32 i;
	for (i = 0; i < 16; i++) {
	runtime·printf("\tf%d:\t%X %X\n", i, m->freghi[i], m->freglo[i]);
	}
	}

	static uint32
	d2f(uint64 d)
	{
	uint32 x;

	runtime·f64to32c(d, &x);
	return x;
	}

	static uint64
	f2d(uint32 f)
	{
	uint64 x;

	runtime·f32to64c(f, &x);
	return x;
	}

	static uint32
	fstatus(bool nan, int32 cmp)
	{
	if(nan)
	return FLAGS_C \| FLAGS_V;
	if(cmp == 0)
	return FLAGS_Z \| FLAGS_C;
	if(cmp < 0)
	return FLAGS_N;
	return FLAGS_C;
	}

	// returns number of words that the fp instruction
	// is occupying, 0 if next instruction isn't float.
	static uint32
	stepflt(uint32 pc, uint32 regs)
	{
	uint32 i, regd, regm, regn;
	int32 delta;
	uint32 *addr;
	uint64 uval;
	int64 sval;
	bool nan, ok;
	int32 cmp;

	i = *pc;

	if(trace)
	runtime·printf("stepflt %p %x\n", pc, i);

	// special cases
	if((i&0xfffff000) == 0xe59fb000) {
	// load r11 from pc-relative address.
	// might be part of a floating point move
	// (or might not, but no harm in simulating
	// one instruction too many).
	addr = (uint32)((uint8)pc + (i&0xfff) + 8);
	regs[11] = addr[0];

	if(trace)
	runtime·printf("*** cpu R[%d] = *(%p) %x\n",
	11, addr, regs[11]);
	return 1;
	}
	if(i == 0xe08bb00d) {
	// add sp to r11.
	// might be part of a large stack offset address
	// (or might not, but again no harm done).
	regs[11] += regs[13];

	if(trace)
	runtime·printf("*** cpu R[%d] += R[%d] %x\n",
	11, 13, regs[11]);
	return 1;
	}
	if(i == 0xeef1fa10) {
	regs[CPSR] = (regs[CPSR]&0x0fffffff) \| m->fflag;

	if(trace)
	runtime·printf("*** fpsr R[CPSR] = F[CPSR] %x\n", regs[CPSR]);
	return 1;
	}
	if((i&0xff000000) == 0xea000000) {
	// unconditional branch
	// can happen in the middle of floating point
	// if the linker decides it is time to lay down
	// a sequence of instruction stream constants.
	delta = i&0xffffff;
	delta = (delta<<8) >> 8; // sign extend

	if(trace)
	runtime·printf("*** cpu PC += %x\n", (delta+2)*4);
	return delta+2;
	}

	goto stage1;

	stage1: // load/store regn is cpureg, regm is 8bit offset
	regd = i>>12 & 0xf;
	regn = i>>16 & 0xf;
	regm = (i & 0xff) << 2; // PLUS or MINUS ??

	switch(i & 0xfff00f00) {
	default:
	goto stage2;

	case 0xed900a00: // single load
	addr = (uint32*)(regs[regn] + regm);
	m->freglo[regd] = addr[0];

	if(trace)
	runtime·printf("*** load F[%d] = %x\n",
	regd, m->freglo[regd]);
	break;

	case 0xed900b00: // double load
	addr = (uint32*)(regs[regn] + regm);
	m->freglo[regd] = addr[0];
	m->freghi[regd] = addr[1];

	if(trace)
	runtime·printf("*** load D[%d] = %x-%x\n",
	regd, m->freghi[regd], m->freglo[regd]);
	break;

	case 0xed800a00: // single store
	addr = (uint32*)(regs[regn] + regm);
	addr[0] = m->freglo[regd];

	if(trace)
	runtime·printf("*** *(%p) = %x\n",
	addr, addr[0]);
	break;

	case 0xed800b00: // double store
	addr = (uint32*)(regs[regn] + regm);
	addr[0] = m->freglo[regd];
	addr[1] = m->freghi[regd];

	if(trace)
	runtime·printf("*** *(%p) = %x-%x\n",
	addr, addr[1], addr[0]);
	break;
	}
	return 1;

	stage2: // regd, regm, regn are 4bit variables
	regm = i>>0 & 0xf;
	switch(i & 0xfff00ff0) {
	default:
	goto stage3;

	case 0xf3000110: // veor
	m->freglo[regd] = m->freglo[regm]^m->freglo[regn];
	m->freghi[regd] = m->freghi[regm]^m->freghi[regn];

	if(trace)
	runtime·printf("*** veor D[%d] = %x-%x\n",
	regd, m->freghi[regd], m->freglo[regd]);
	break;

	case 0xeeb00b00: // D[regd] = const(regn,regm)
	regn = (regn<<4) \| regm;
	regm = 0x40000000UL;
	if(regn & 0x80)
	regm \|= 0x80000000UL;
	if(regn & 0x40)
	regm ^= 0x7fc00000UL;
	regm \|= (regn & 0x3f) << 16;
	m->freglo[regd] = 0;
	m->freghi[regd] = regm;

	if(trace)
	runtime·printf("*** immed D[%d] = %x-%x\n",
	regd, m->freghi[regd], m->freglo[regd]);
	break;

	case 0xeeb00a00: // F[regd] = const(regn,regm)
	regn = (regn<<4) \| regm;
	regm = 0x40000000UL;
	if(regn & 0x80)
	regm \|= 0x80000000UL;
	if(regn & 0x40)
	regm ^= 0x7e000000UL;
	regm \|= (regn & 0x3f) << 19;
	m->freglo[regd] = regm;

	if(trace)
	runtime·printf("*** immed D[%d] = %x\n",
	regd, m->freglo[regd]);
	break;

	case 0xee300b00: // D[regd] = D[regn]+D[regm]
	runtime·fadd64c(getd(regn), getd(regm), &uval);
	putd(regd, uval);

	if(trace)
	runtime·printf("*** add D[%d] = D[%d]+D[%d] %x-%x\n",
	regd, regn, regm, m->freghi[regd], m->freglo[regd]);
	break;

	case 0xee300a00: // F[regd] = F[regn]+F[regm]
	runtime·fadd64c(f2d(m->freglo[regn]), f2d(m->freglo[regm]), &uval);
	m->freglo[regd] = d2f(uval);

	if(trace)
	runtime·printf("*** add F[%d] = F[%d]+F[%d] %x\n",
	regd, regn, regm, m->freglo[regd]);
	break;

	case 0xee300b40: // D[regd] = D[regn]-D[regm]
	runtime·fsub64c(getd(regn), getd(regm), &uval);
	putd(regd, uval);

	if(trace)
	runtime·printf("*** sub D[%d] = D[%d]-D[%d] %x-%x\n",
	regd, regn, regm, m->freghi[regd], m->freglo[regd]);
	break;

	case 0xee300a40: // F[regd] = F[regn]-F[regm]
	runtime·fsub64c(f2d(m->freglo[regn]), f2d(m->freglo[regm]), &uval);
	m->freglo[regd] = d2f(uval);

	if(trace)
	runtime·printf("*** sub F[%d] = F[%d]-F[%d] %x\n",
	regd, regn, regm, m->freglo[regd]);
	break;

	case 0xee200b00: // D[regd] = D[regn]*D[regm]
	runtime·fmul64c(getd(regn), getd(regm), &uval);
	putd(regd, uval);

	if(trace)
	runtime·printf("*** mul D[%d] = D[%d]*D[%d] %x-%x\n",
	regd, regn, regm, m->freghi[regd], m->freglo[regd]);
	break;

	case 0xee200a00: // F[regd] = F[regn]*F[regm]
	runtime·fmul64c(f2d(m->freglo[regn]), f2d(m->freglo[regm]), &uval);
	m->freglo[regd] = d2f(uval);

	if(trace)
	runtime·printf("*** mul F[%d] = F[%d]*F[%d] %x\n",
	regd, regn, regm, m->freglo[regd]);
	break;

	case 0xee800b00: // D[regd] = D[regn]/D[regm]
	runtime·fdiv64c(getd(regn), getd(regm), &uval);
	putd(regd, uval);

	if(trace)
	runtime·printf("*** div D[%d] = D[%d]/D[%d] %x-%x\n",
	regd, regn, regm, m->freghi[regd], m->freglo[regd]);
	break;

	case 0xee800a00: // F[regd] = F[regn]/F[regm]
	runtime·fdiv64c(f2d(m->freglo[regn]), f2d(m->freglo[regm]), &uval);
	m->freglo[regd] = d2f(uval);

	if(trace)
	runtime·printf("*** div F[%d] = F[%d]/F[%d] %x\n",
	regd, regn, regm, m->freglo[regd]);
	break;

	case 0xee000b10: // S[regn] = R[regd] (MOVW) (regm ignored)
	m->freglo[regn] = regs[regd];

	if(trace)
	runtime·printf("*** cpy S[%d] = R[%d] %x\n",
	regn, regd, m->freglo[regn]);
	break;

	case 0xee100b10: // R[regd] = S[regn] (MOVW) (regm ignored)
	regs[regd] = m->freglo[regn];

	if(trace)
	runtime·printf("*** cpy R[%d] = S[%d] %x\n",
	regd, regn, regs[regd]);
	break;
	}
	return 1;

	stage3: // regd, regm are 4bit variables
	switch(i & 0xffff0ff0) {
	default:
	goto done;

	case 0xeeb00a40: // F[regd] = F[regm] (MOVF)
	m->freglo[regd] = m->freglo[regm];

	if(trace)
	runtime·printf("*** F[%d] = F[%d] %x\n",
	regd, regm, m->freglo[regd]);
	break;

	case 0xeeb00b40: // D[regd] = D[regm] (MOVD)
	m->freglo[regd] = m->freglo[regm];
	m->freghi[regd] = m->freghi[regm];

	if(trace)
	runtime·printf("*** D[%d] = D[%d] %x-%x\n",
	regd, regm, m->freghi[regd], m->freglo[regd]);
	break;

	case 0xeeb10bc0: // D[regd] = sqrt D[regm]
	math·sqrtC(getd(regm), &uval);
	putd(regd, uval);

	if(trace)
	runtime·printf("*** D[%d] = sqrt D[%d] %x-%x\n",
	regd, regm, m->freghi[regd], m->freglo[regd]);
	break;

	case 0xeeb40bc0: // D[regd] :: D[regm] (CMPD)
	runtime·fcmp64c(getd(regd), getd(regm), &cmp, &nan);
	m->fflag = fstatus(nan, cmp);

	if(trace)
	runtime·printf("*** cmp D[%d]::D[%d] %x\n",
	regd, regm, m->fflag);
	break;

	case 0xeeb40ac0: // F[regd] :: F[regm] (CMPF)
	runtime·fcmp64c(f2d(m->freglo[regd]), f2d(m->freglo[regm]), &cmp, &nan);
	m->fflag = fstatus(nan, cmp);

	if(trace)
	runtime·printf("*** cmp F[%d]::F[%d] %x\n",
	regd, regm, m->fflag);
	break;

	case 0xeeb70ac0: // D[regd] = F[regm] (MOVFD)
	putd(regd, f2d(m->freglo[regm]));

	if(trace)
	runtime·printf("*** f2d D[%d]=F[%d] %x-%x\n",
	regd, regm, m->freghi[regd], m->freglo[regd]);
	break;

	case 0xeeb70bc0: // F[regd] = D[regm] (MOVDF)
	m->freglo[regd] = d2f(getd(regm));

	if(trace)
	runtime·printf("*** d2f F[%d]=D[%d] %x-%x\n",
	regd, regm, m->freghi[regd], m->freglo[regd]);
	break;

	case 0xeebd0ac0: // S[regd] = F[regm] (MOVFW)
	runtime·f64tointc(f2d(m->freglo[regm]), &sval, &ok);
	if(!ok \|\| (int32)sval != sval)
	sval = 0;
	m->freglo[regd] = sval;

	if(trace)
	runtime·printf("*** fix S[%d]=F[%d] %x\n",
	regd, regm, m->freglo[regd]);
	break;

	case 0xeebc0ac0: // S[regd] = F[regm] (MOVFW.U)
	runtime·f64tointc(f2d(m->freglo[regm]), &sval, &ok);
	if(!ok \|\| (uint32)sval != sval)
	sval = 0;
	m->freglo[regd] = sval;

	if(trace)
	runtime·printf("*** fix unsigned S[%d]=F[%d] %x\n",
	regd, regm, m->freglo[regd]);
	break;

	case 0xeebd0bc0: // S[regd] = D[regm] (MOVDW)
	runtime·f64tointc(getd(regm), &sval, &ok);
	if(!ok \|\| (int32)sval != sval)
	sval = 0;
	m->freglo[regd] = sval;

	if(trace)
	runtime·printf("*** fix S[%d]=D[%d] %x\n",
	regd, regm, m->freglo[regd]);
	break;

	case 0xeebc0bc0: // S[regd] = D[regm] (MOVDW.U)
	runtime·f64tointc(getd(regm), &sval, &ok);
	if(!ok \|\| (uint32)sval != sval)
	sval = 0;
	m->freglo[regd] = sval;

	if(trace)
	runtime·printf("*** fix unsigned S[%d]=D[%d] %x\n",
	regd, regm, m->freglo[regd]);
	break;

	case 0xeeb80ac0: // D[regd] = S[regm] (MOVWF)
	cmp = m->freglo[regm];
	if(cmp < 0) {
	runtime·fintto64c(-cmp, &uval);
	putf(regd, d2f(uval));
	m->freglo[regd] ^= 0x80000000;
	} else {
	runtime·fintto64c(cmp, &uval);
	putf(regd, d2f(uval));
	}

	if(trace)
	runtime·printf("*** float D[%d]=S[%d] %x-%x\n",
	regd, regm, m->freghi[regd], m->freglo[regd]);
	break;

	case 0xeeb80a40: // D[regd] = S[regm] (MOVWF.U)
	runtime·fintto64c(m->freglo[regm], &uval);
	putf(regd, d2f(uval));

	if(trace)
	runtime·printf("*** float unsigned D[%d]=S[%d] %x-%x\n",
	regd, regm, m->freghi[regd], m->freglo[regd]);
	break;

	case 0xeeb80bc0: // D[regd] = S[regm] (MOVWD)
	cmp = m->freglo[regm];
	if(cmp < 0) {
	runtime·fintto64c(-cmp, &uval);
	putd(regd, uval);
	m->freghi[regd] ^= 0x80000000;
	} else {
	runtime·fintto64c(cmp, &uval);
	putd(regd, uval);
	}

	if(trace)
	runtime·printf("*** float D[%d]=S[%d] %x-%x\n",
	regd, regm, m->freghi[regd], m->freglo[regd]);
	break;

	case 0xeeb80b40: // D[regd] = S[regm] (MOVWD.U)
	runtime·fintto64c(m->freglo[regm], &uval);
	putd(regd, uval);

	if(trace)
	runtime·printf("*** float unsigned D[%d]=S[%d] %x-%x\n",
	regd, regm, m->freghi[regd], m->freglo[regd]);
	break;
	}
	return 1;

	done:
	if((i&0xff000000) == 0xee000000 \|\|
	(i&0xff000000) == 0xed000000) {
	runtime·printf("stepflt %p %x\n", pc, i);
	fabort();
	}
	return 0;
	}

	#pragma textflag 7
	uint32*
	runtime·_sfloat2(uint32 *lr, uint32 r0)
	{
	uint32 skip;

	skip = stepflt(lr, &r0);
	if(skip == 0) {
	runtime·printf("sfloat2 %p %x\n", lr, *lr);
	fabort(); // not ok to fail first instruction
	}

	lr += skip;
	while(skip = stepflt(lr, &r0))
	lr += skip;
	return lr;
	}